vs10/bm/bmvmin.h

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#ifndef BMVMIN__H__INCLUDED__
#define BMVMIN__H__INCLUDED__
/*
Copyright(c) 2002-2005 Anatoliy Kuznetsov(anatoliy_kuznetsov at yahoo.com)

Permission is hereby granted, free of charge, to any person 
obtaining a copy of this software and associated documentation 
files (the "Software"), to deal in the Software without restriction, 
including without limitation the rights to use, copy, modify, merge, 
publish, distribute, sublicense, and/or sell copies of the Software, 
and to permit persons to whom the Software is furnished to do so, 
subject to the following conditions:

The above copyright notice and this permission notice shall be included 
in all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, 
EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES 
OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. 
IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, 
DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, 
ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR 
OTHER DEALINGS IN THE SOFTWARE.

For more information please visit:  http://bmagic.sourceforge.net

*/

#ifdef _MSC_VER
#pragma warning( push )
#pragma warning( disable : 4100)
#endif

namespace bm
{


#define BM_MINISET_GAPLEN (bm::gap_len_table<true>::_len[0])
#define BM_MINISET_ARRSIZE(x) ((x / 32) + ( (x % 32) && 1 ))

template <class A, size_t N> class miniset
{
public:

    miniset() 
        : m_buf(0),
          m_type(1)
    {}

    miniset(const miniset& mset)
    {
        if (mset.m_buf)
        {
            if (mset.m_type)
                init_gapbuf(mset.m_buf);
            else
                init_bitbuf(mset.m_buf);
        }
        else
        {
            m_type = mset.m_type;
            m_buf = 0;
        }
    }

    ~miniset()
    {
        if (m_buf)
        {
            A::deallocate(m_buf, m_type ? 
                (BM_MINISET_GAPLEN / (sizeof(bm::word_t) / sizeof(bm::gap_word_t)))
                : 
                (BM_MINISET_ARRSIZE(N)));
        }
    }

    unsigned test(bm::id_t n) const 
    { 
        return
            !m_buf ? 0 
            :
            m_type ? 
              gap_test((gap_word_t*)m_buf, n)
              : 
              m_buf[n>>bm::set_word_shift] & (1<<(n & bm::set_word_mask));
    }

    void set(bm::id_t n, bool val=true)
    {
        if (m_type == 0)
        {
            if (!m_buf)
            {
                if (!val) return;
                init_bitbuf(0);
            }

            unsigned nword  = n >> bm::set_word_shift; 
            unsigned mask = unsigned(1) << (n & bm::set_word_mask);

            val ? (m_buf[nword] |= mask) : (m_buf[nword] &= ~mask);
        }
        else
        {
            if (!m_buf)
            {
                if (!val) return;
                init_gapbuf(0);
            }
            
            unsigned is_set;
            unsigned new_block_len = 
                gap_set_value(val, (gap_word_t*)m_buf, n, &is_set);

            if (new_block_len > unsigned(BM_MINISET_GAPLEN-4))
            {
                convert_buf();
            }
        }
    }

    unsigned mem_used() const
    {
        return sizeof(*this) +
               m_buf ? 
                 (m_type ? (BM_MINISET_GAPLEN * sizeof(gap_word_t))
                        : (BM_MINISET_ARRSIZE(N) * sizeof(bm::word_t)))
                : 0; 
    }

    void swap(miniset& mset)
    {
        bm::word_t* buftmp = m_buf;
        m_buf = mset.m_buf;
        mset.m_buf = buftmp;
        unsigned typetmp = m_type;
        m_type = mset.m_type;
        mset.m_type = typetmp;
    }


private:

    void init_bitbuf(bm::word_t* buf)
    {
        unsigned arr_size = BM_MINISET_ARRSIZE(N);
        m_buf = A::allocate(arr_size, 0);
        if (buf)
        {
            ::memcpy(m_buf, buf, arr_size * sizeof(bm::word_t));
        }
        else
        {
            ::memset(m_buf, 0, arr_size * sizeof(bm::word_t));
        }
        m_type = 0;
    }

    void init_gapbuf(bm::word_t* buf)
    {
        unsigned arr_size = 
            BM_MINISET_GAPLEN / (sizeof(bm::word_t) / sizeof(bm::gap_word_t));
        m_buf = A::allocate(arr_size, 0);
        if (buf)
        {
            ::memcpy(m_buf, buf, arr_size * sizeof(bm::word_t));
        }
        else
        {
            *m_buf = 0;
            gap_set_all((gap_word_t*)m_buf, bm::gap_max_bits, 0);
        }
        m_type = 1;
    }

    void convert_buf()
    {
        unsigned arr_size = BM_MINISET_ARRSIZE(N);
        bm::word_t* buf = A::allocate(arr_size, 0);

        gap_convert_to_bitset(buf, (gap_word_t*) m_buf, arr_size);
        arr_size = 
            BM_MINISET_GAPLEN / (sizeof(bm::word_t) / sizeof(bm::gap_word_t));
        A::deallocate(m_buf, arr_size);
        m_buf = buf;
        m_type = 0;
    }

private:
    bm::word_t*   m_buf;      
    unsigned      m_type;     
};


template<size_t N> class bvmini
{
public:

    bvmini(int start_strategy = 0) 
    {
        ::memset(m_buf, 0, sizeof(m_buf));
    }

    bvmini(const bvmini& mset)
    {
        ::memcpy(m_buf, mset.m_buf, sizeof(m_buf));
    }


    unsigned test(bm::id_t n) const 
    { 
        return m_buf[n>>bm::set_word_shift] & (1<<(n & bm::set_word_mask));
    }

    void set(bm::id_t n, bool val=true)
    {
        unsigned nword  = n >> bm::set_word_shift; 
        unsigned mask = unsigned(1) << (n & bm::set_word_mask);

        val ? (m_buf[nword] |= mask) : (m_buf[nword] &= ~mask);
    }

    unsigned mem_used() const
    {
        return sizeof(*this);
    }

    void swap(bvmini& mset)
    {
        for (unsigned i = 0; i < BM_MINISET_ARRSIZE(N); ++i)
        {
            bm::word_t tmp = m_buf[i];
            m_buf[i] = mset.m_buf[i];
            mset.m_buf[i] = tmp;
        }
    }

private:
    bm::word_t   m_buf[BM_MINISET_ARRSIZE(N)];
};


template<class A> class bvector_mini
{
public:
    bvector_mini(unsigned size) 
      : m_buf(0),
        m_size(size)
    {
        unsigned arr_size = (size / 32) + 1; 
        m_buf = A::allocate(arr_size, 0);
        ::memset(m_buf, 0, arr_size * sizeof(unsigned));
    }
    bvector_mini(const bvector_mini& bvect)
       : m_size(bvect.m_size)
    {
        unsigned arr_size = (m_size / 32) + 1;
        m_buf = A::allocate(arr_size, 0);
        ::memcpy(m_buf, bvect.m_buf, arr_size * sizeof(unsigned));        
    }

    ~bvector_mini()
    {
        A::deallocate(m_buf, (m_size / 32) + 1); 
    }

    int is_bit_true(unsigned pos) const
    {
        unsigned char  mask = (unsigned char)((char)0x1 << (pos & 7));
        unsigned char* offs = (unsigned char*)m_buf + (pos >> 3); // m_buf + (pos/8)

        return (*offs) & mask;
    }

    void set_bit(unsigned pos)
    {
        unsigned char  mask = (unsigned char)(0x1 << (pos & 7));
        unsigned char* offs = (unsigned char*)m_buf + (pos >> 3); 
        *offs |= mask;
    }


    void clear_bit(unsigned pos)
    {
        unsigned char  mask = (unsigned char)(0x1 << (pos & 7));
        unsigned char* offs = (unsigned char*)m_buf + (pos >> 3); 

        *offs &= ~mask;
    }

    unsigned bit_count() const
    {
        register unsigned count = 0;
        const unsigned* end = m_buf + (m_size / 32)+1;    

        for (unsigned* start = m_buf; start < end; ++start)
        {
            register unsigned value = *start;
            for (count += (value!=0); value &= value - 1; ++count);
        }
        return count;
    }

    int compare(const bvector_mini& bvect)
    {
        unsigned cnt1 = bit_count();
        unsigned cnt2 = bvect.bit_count();

        if (!cnt1 && !cnt2) return 0;

        unsigned cnt_min = cnt1 < cnt2 ? cnt1 : cnt2;

        if (!cnt_min) return cnt1 ? 1 : -1;

        unsigned idx1 = get_first();
        unsigned idx2 = bvect.get_first();

        for (unsigned i = 0; i < cnt_min; ++i)
        {
            if (idx1 != idx2)
            {
                return idx1 < idx2 ? 1 : -1;
            }
            idx1 = get_next(idx1);
            idx2 = bvect.get_next(idx2);
        }

        //BM_ASSERT(idx1==0 || idx2==0);

        if (idx1 != idx2)
        {
            if (!idx1) return -1;
            if (!idx2) return  1;
            return idx1 < idx2 ? 1 : -1;
        }

        return 0;
    }


    unsigned get_first() const
    {
        unsigned pos = 0;
        const unsigned char* ptr = (unsigned char*) m_buf;

        for (unsigned i = 0; i < (m_size/8)+1; ++i)
        {
            register unsigned char w = ptr[i];


            if (w != 0)
            {
                while ((w & 1) == 0)
                {
                    w >>= 1;
                    ++pos;
                }
                return pos;
            }
            pos += sizeof(unsigned char) * 8;
        }
        return 0;
    }


    unsigned get_next(unsigned idx) const
    {
        register unsigned i;

        for (i = idx+1; i < m_size; ++i)
        {
            unsigned char* offs = (unsigned char*)m_buf + (i >> 3); 
            if (*offs)
            {
                unsigned char mask = (unsigned char)((char)0x1 << (i & 7));

                if (*offs & mask)
                {
                    return i;
                }
            }
            else
            {
                i += 7;
            }
        }
        return 0;
    }


    void combine_and(const bvector_mini& bvect)
    {
        const unsigned* end = m_buf + (m_size / 32)+1;
    
        const unsigned* src = bvect.get_buf();

        for (unsigned* start = m_buf; start < end; ++start)
        {
            *start &= *src++;
        }
    }

    void combine_xor(const bvector_mini& bvect)
    {
        const unsigned* end = m_buf + (m_size / 32)+1;
    
        const unsigned* src = bvect.get_buf();

        for (unsigned* start = m_buf; start < end; ++start)
        {
            *start ^= *src++;
        }
    }


    void combine_or(const bvector_mini& bvect)
    {
        const unsigned* end = m_buf + (m_size / 32)+1;
    
        const unsigned* src = bvect.get_buf();

        for (unsigned* start = m_buf; start < end; ++start)
        {
            *start |= *src++;
        }
    }

    void combine_sub(const bvector_mini& bvect)
    {
        const unsigned* end = m_buf + (m_size / 32)+1;
    
        const unsigned* src = bvect.get_buf();

        for (unsigned* start = m_buf; start < end; ++start)
        {
            *start &= ~(*src++);
        }
    }

    const unsigned* get_buf() const { return m_buf; }
    unsigned mem_used() const
    {
        return sizeof(bvector_mini) + (m_size / 32) + 1;
    }

    void swap(bvector_mini& bvm)
    {
        BM_ASSERT(m_size == bvm.m_size);
        bm::word_t* buftmp = m_buf;
        m_buf = bvm.m_buf;
        bvm.m_buf = buftmp;
    }

private:
    bm::word_t*   m_buf;
    unsigned      m_size;
};



} // namespace bm

#ifdef _MSC_VER
#pragma warning( pop )
#endif

#endif